Pressurized fluid apparatus

ABSTRACT

Pressurized fluid apparatus including a pressurized fluid container, a pipe arranged for flow therethrough of the pressurized fluid into the container, a valve operatively connected to an end of the pipe disposed in the container, and a float attached to the valve, wherein the float is buoyed generally upwards by the pressurized fluid filling the container, such that when the float has been moved a predetermined amount, the float closes the valve and substantially stops flow of the pressurized fluid into the container, and wherein the float is insertable through an upper opening of the container, and wherein the valve is rotatably attached to the pipe, the valve being closed by an angular upward movement of the float, characterized by the valve including a tube with a longitudinal bore having a longitudinal axis formed therein, and a piston slidingly disposed in the tube, wherein only when the float is generally perpendicular to the longitudinal axis, the piston sealingly abuts an internal end face of the tube, thereby closing the valve.

The present invention relates to apparatus and methods for fillingpressurized fluid containers.

BACKGROUND OF THE INVENTION

Pressurized fluid containers, such as pressurized LPG containers, aretypically filled by transferring therein a fluid at high pressure from apressurized fluid source, such as a tanker truck. The container isgenerally designed in the art such that when it has been filled toapproximately 80% of its total volume, fluid begins to escape through arelief valve, thereby signaling that the container has been adequatelyfilled and that the filling operation should be terminated.

Some municipal codes forbid allowing fluid, such as LPG, from escapingto the environment to signal the end of the filling process. Therefore,it is desirable to provide apparatus and methods for filling pressurizedfluid containers without any fluid escaping to the environment.

SUMMARY OF THE INVENTION

The present invention seeks to provide improved apparatus and methodsfor filling pressurized fluid containers without any fluid escaping tothe environment.

There is thus provided in accordance with a preferred embodiment of thepresent invention pressurized fluid apparatus including, a pressurizedfluid container, a pipe arranged for flow therethrough of thepressurized fluid into the container, a valve operatively connected toan end of the pipe disposed in the container, and a float attached tothe valve, wherein the float is buoyed generally upwards by thepressurized fluid filling, the container, such that when the float hasbeen moved a predetermined amount, the float closes the valve andsubstantially stops flow of the pressurized fluid into the container,and wherein the float is insertable through an upper opening of thecontainer, and wherein the valve is rotatably attached to the pipe, thevalve being closed by an angular upward movement of the float,characterized by the valve including a tube with a longitudinal borehaving, a longitudinal axis formed therein, and a piston slidinglydisposed in the tube, wherein only when the float is generallyperpendicular to the longitudinal axis, the piston sealingly abuts aninternal end face of the tube, thereby closing, the valve.

In accordance with a preferred embodiment of the present invention thepiston has an enlarged end and the bore has an enlarged portion toaccommodate and receive therein the enlarged end, and wherein movementof the enlarged end along, the longitudinal axis of the tube isconstrained between a shoulder and an end surface of the enlargedportion of the bore.

Further in accordance with a preferred embodiment of the presentinvention interface member extends from the piston and protrudes throughan aperture formed in the tube, and the float is mounted on a float arm,and wherein an end of the float arm has a generally flat end portionwhich initially abuts against the interface member and a generallyarcuate portion which initially contacts a low-friction portion of theinterface member, and wherein the piston sealingly abuts the internalend face of the tube only when the arcuate portion slides off thelow-friction portion.

Still further in accordance with a preferred embodiment of the presentinvention an interface member extends from the piston and protrudesthrough an aperture formed in the tube, and the float is mounted on afloat arm, and wherein an end of the float arm has a generally flat endportion which initially abuts against the interface member and agenerally arcuate portion which initially contacts a low-frictionportion of the interface member, and wherein the piston sealingly abutsthe internal end face of the tube only when the flat end portion isrotated about 90° from the interface member.

Additionally in accordance with a preferred embodiment of the presentinvention the piston is shaped to ensure laminar flow of a pressurizedfluid therearound.

Preferably a bypass passageway is provided for conducting therethroughfluid, even during filling, of the container.

It is a particular feature of the present invention that the valve whenclosed, is preferably not hermetically closed, but rather a small amountof fluid is purposely allowed to leak into the container. The smallleakage ensures that no damage will occur to the pipe due to pressurebuild-up.

In accordance with a preferred embodiment of the present invention abiasing device imparts a biasing force on the piston, the biasing, forcebeing, of a magnitude such that if the tube contains a predeterminedamount of the pressurized fluid then the predetermined amount issufficient to overcome the biasing force and seat the piston against theinternal end face, and that if the tube contains less than thepredetermined amount, the biasing, device urges the piston away from theinternal end face of the tube. Preferably the biasing device is disposedin a bore formed in the piston.

Additionally in accordance with a preferred embodiment of the presentinvention a needle hole is formed in a wall of the float, the hole beingsufficiently small such that generally only vapors of the pressurizedfluid and not liquid of the pressurized fluid can enter the float.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention will be understood and appreciated more fully fromthe following detailed description, taken in conjunction with thedrawings in which:

FIG 1. is a simplified pictorial illustration of filling apparatusconstructed and operative in accordance with a preferred embodiment ofthe present invention;

FIG. 2 is a simplified, partially sectional illustration of a valve ofthe filling apparatus of FIG. 1, constructed and operative in accordancewith a preferred embodiment of the present invention, in an openposition;

FIG. 3 is a simplified, partially sectional illustration of insertingthe filling apparatus of FIG. 1 into a pressurized fluid container;

FIG. 4A is a simplified, partially sectional illustration of thefilling, apparatus of FIG. 1 fixedly attached to a pressurized fluidcontainer;

FIG. 4B is a simplified, partially sectional illustration of a floatclosing the valve of filling apparatus of FIG. 1, in accordance with apreferred embodiment of the present invention, thereby stopping fillingof a pressurized fluid container;

FIGS. 5 and 6 are simplified, partially sectional illustrations of apressure valve, constructed and operative in accordance with a preferredembodiment of the present invention, respectively before and aftersubstantially sealing filling apparatus of FIG 1; and

FIG. 7A and 7B are simplified, partially sectional illustrations ofanother valve useful with the filling apparatus of FIG. 1, constructedand operative in accordance with another preferred embodiment of thepresent invention, respectively in an open position and in a closedposition.

DETAILED DESCRIPTION OF A PREFERRED EMBODIMENT

Reference is now made to FIG. 1 which illustrates filling apparatus 10,constructed and operative in accordance with a preferred embodiment ofthe present invention.

Filling apparatus 10 preferably includes a tee 12 which includes a firstthreaded branch 14 for attachment thereat to a source of pressurizedfluid (not shown), such as pressurized LPG. A second threaded branch 16is preferably attached to a consumer valve 18. Valve 18 preferablyincludes a handle 20 for closing/opening thereof, a threaded coupling 22for attachment thereat to a consumer fluid supply line (not shown), anda relief valve 24. A third threaded branch 26 of tee 12 is preferablyattached to an upper end 28 of a pipe 30. A lower end 32 of pipe 30 ispreferably attached to and in fluid communication with a valve 40.

Reference is now made to FIG. 2 which illustrates valve 40, constructedand operative in accordance with a preferred embodiment of the presentinvention, in an open position. Valve 40 includes a tube 42 with alongitudinal bore 44 formed therein. Bore 44 has a threaded end 46 whichis threadably connected to lower end 32 of pipe 30 (FIG. 1). A piston 48is slidingly disposed in tube 42. Piston 48 is preferably generallycylindrical in shape and has an enlarged end 50. Bore 44 has an enlargedportion 52 to accommodate and receive therein enlarged end 50. It isseen in FIG. 2 that movement of enlarged end 50 along a longitudinalaxis 54 of tube 42 is constrained between a shoulder 56 and an endsurface 58 of enlarged portion 52. Piston 48 may be fluted or otherwisesuitably shaped along the non-enlarged portion, indicated by referencenumeral 59, to ensure laminar flow of a pressurized fluid 60 therearoundand to minimize pressure drop of the flow.

Extending from enlarged end 50 and protruding through an aperture 62formed in tube 42 is an interface member 64. Interface member 64 may beconstructed integrally as one piece with piston 48, or alternatively maybe attached to piston 48 by means of a screw 66. A roller 68 may berotatably attached to a portion 70 of interface member 64 offset fromaxis 54.

A float 72 is mounted on a float arm 74 which is pivotally attached to ablock 76 fixedly attached to tube 42. An end 78 of float arm 74 has agenerally flat end portion 80 which initially abuts against interfacemember 64 and a generally arcuate portion 82 which initially contactsroller 68. In the position of FIG. 2, enlarged end 50 of piston 48 doesnot initially rest against end surface 58, and pressurized fluid 60 isfree to flow through aperture 62 into a pressurized container (not shownin FIG. 2).

Reference is now made to FIG. 3 which illustrates inserting fillingapparatus 10 into a pressurized fluid container 90. Consumer valve 18has been omitted for clarity. It is seen that float 72 may beconveniently rotated relative to pipe 30 so as to permit insertion offilling, apparatus 10 through a neck 92 of pressurized fluid container90.

Reference is now made to FIG. 4A which illustrates filling apparatus 10fixedly attached to pressurized fluid container. Pressurized fluid 60may be introduced from a fluid source (not shown) and flow through firstthreaded branch 14 and pipe 30. Since float 72 is positioned at agenerally obtuse angle with respect to pipe 30, pressurized fluid 60 isfree to flow through aperture 62 into container 90.

Preferably a bypass passageway 94 is formed between pipe 30 and thirdthreaded branch 26. Bypass passageway 94 is preferably in fluidcommunication with an orifice 96 formed in second threaded branch 16. Itis a particular feature of the present invention that a fluid 98, suchas LPG vapor, can be conducted through bypass passageway 94 even duringfilling of container 90. In this way, a consumer can constantly usefluid 98, such as for home cooking, without interruption, even during,filling, of container 90.

Reference is now made to FIG. 4B which illustrates the position offilling apparatus 10 upon further filling of container 90 withpressurized fluid 60. For clarity of detail, container 90 is omitted inFIG. 4B. Upon sufficient filling, of container 90, float 72 is buoyed byfluid 60 and float arm 74 is approximately at 90° to axis 54. In thisposition, arcuate portion 82 has slid off roller 68 and flat end portion80 has been rotated about 90° from interface member 64. The changedpositions of arcuate portion 82 and flat end portion 80 permit enlargedend 50 of piston 48 to seat against end surface 58, thereby preventingpressurized fluid 60 from flowing through aperture 62 into container 90.Thus filling apparatus 10 automatically stops filling, container 90without any need for fluid to escape to the environment to signal whento stop filling, container 90.

It is noted that the purpose of roller 68 is to provide a very lowfriction surface for arcuate portion 82 to move against. Alternatively,roller 68 may be replaced with a non-rolling, low friction surface.

Reference is now made to FIGS. 5 and 6 which are simplified, partiallysectional illustrations of a pressure valve 100, constructed andoperative in accordance with a preferred embodiment of the presentinvention.

Pressure valve 100 preferably includes a body 102 which is formed with abore 104 along a longitudinal axis 106, a transverse inlet bore 108 influid communication with an inlet coupling 110 and a transverse outletbore 112 in fluid communication with an outlet coupling 114. Outletcoupling 114 is connectable to first threaded branch 14 (FIG. 1).

Slidingly disposed in bore 104 is a first piston 116 which includes abulbous end 118 and an O-ring 120 proximal to bulbous end 118. Oppositeto bulbous end 118, first piston 116 has a generally cylindricalextension 122 which has a smaller diameter than the rest of first piston116. A shoulder 124 is formed at the junction of extension 122 to therest of first piston 116. A second piston 126 is also slidingly disposedin bore 104 and is preferably connected to first piston 116 by athreaded pin 128, there being a gap 130 between the two pistons 116 and126.

In the position shown in FIG. 5, pressurized fluid (50 may flow throughinlet coupling 110, inlet bore 108, gap 130, outlet bore 112 and outletcoupling, 114 to first threaded branch 14 (FIG. 1). Second piston 126preferably substantially hermetically seals any flow of pressurizedfluid 60 from leaking, therethrough. However, in first piston 116, onlyextension 122 hermetically seals flow of pressurized fluid 60 fromleaking, therethrough, whereas the rest of first piston does not sealflow of pressurized fluid 60 from leaking, therethrough. This is becauseO-ring 120, in the position of FIG. 5, is opposite inlet bore 108 anddoes not seat fluid flow towards the portion of bore 104 in which isdisposed first piston 116. Thus fluid 60 is free to flow towardsextension 122 and is constrained to apply fluid pressure againstshoulder 124 in the direction of an arrow 132. As long as fluid 60 flowsthrough gap 130, however, the fluid force on shoulder 124 does not causefirst piston 116 to slide in bore 104 in the direction of arrow 132because the area of shoulder 124 is smaller than the full area ofbulbous end 118.

FIG. 6 illustrates the operation of pressure valve 100 when pressurizedfluid 60 ceases to flow through gap 130, e.g., when container 90 issufficiently filled. The remainder of fluid 60 continues to flow thoughinlet bore 108 and leaks through the space between first piston 116 andbore 104. Fluid 60 flows towards extension 122 and applies fluidpressure against shoulder 124 in the direction of arrow 132, therebycausing first piston 116 to slide in bore 104 in the direction of arrow132. O-ring 120 then seals inlet bore 108 from outlet bore 112 so thatno more fluid 60 flows to outlet bore 112.

It is a particular feature of the present invention that enlarged end 50of piston 48 preferably does not hermetically seal flow of fluid 60 whenin the position shown in FIG. 4B. Rather a small amount of fluid ispurposely allowed to leak into container 90. The reason is that afterpressure valve 100 has substantially blocked flow to pipe 30 and a userhas removed pressure valve 100 from filling apparatus 10, a column ofpressurized fluid 60 remains in pipe 30. If there were no leakage intocontainer 90 via enlarged end 50, pressurized fluid 60 remaining in pipe30 could possibly cause rupture of pipe 30, such as during temperaturechanges. The small leakage at enlarged end 50 ensures that no damagewill occur due to pressure build-up and temperature change.

Reference is now made to FIGS. 7A and 7B which illustrate another valve150 usefull with filling apparatus 10, constructed and operative inaccordance with another preferred embodiment of the present invention.Valve 150 is similarly constructed to valve 40, with like numeralsdesignating like elements. Valve 150 differs from valve 40 in thatinstead of interface member 64 extending from enlarged end 50 of piston48 (as described previously with reference to FIG. 2), an interfacemember 152 protrudes through aperture 62 formed in tube 42. Interfacemember 152 may be constructed integrally as one piece with piston 48, oralternatively may be attached to piston 48 by means of a screw (notshown).

A float 154 is mounted on float arm 74 which, as mentioned above, ispivotally attached to block 76 fixedly attached to tube 42. An end 156of float arm 74 has a generally, flat end portion 158 which initiallyabuts against a bottom portion 160 of interface member 152. End 156 alsopreferably includes a tongue 162 which is adapted to fit in or abutagainst a groove 164 formed in interface member 152. It is noted thatpreferably tongue 102 does not abut against the upper bounds of groove164.

In the embodiment of FIGS. 7A and 7B, a slanted bore 166 is formed inpiston 48, extending from enlarged end 50 into non-enlarged portion 59.A pin 168 is disposed in bore 166 and biased therein by a biasing devicesuch as a spring 170.

In the position of FIG. 7A (as similarly described above with referenceto FIG. 2), enlarged end 50 of piston 48 does not initially rest againstis free to flow through aperture 62 into a pressurized container (notshown in FIG. 7A). A stopper pin 172 may be attached to interface member152 to limit the upward travel (in the sense of FIG. 7A) of piston 48.Pin 168 merely rests on an edge of surface 58 and does not interferewith the flow of fluid 60.

Reference is now made to FIG. 7B which illustrates the position offilling apparatus 10 upon further filling of container 90 (FIG. 3) withpressurized fluid 60. For clarity of detail, container 90 is omitted inFIG. 7B. Upon sufficient filling of container 90, float 154 is buoyed byfluid 60 and float arm 74 is approximately at 90° to axis 54. In thisposition, flat end portion 158 has slid off bottom portion 160 and hasbeen rotated about 90° from interface member 152. The changed positionof flat end portion 158 permits enlarged end 50 of piston 48 to seatagainst end surface 58, thereby preventing pressurized fluid 60 fromflowing, through aperture 62 into container 90. Thus, by means of valve150, filling, apparatus 10 automatically stops filling container 90without any need for fluid to escape to the environment to signal whento stop filling container 90.

The purpose of spring 170 is now explained. First threaded branch 14(FIG. 1) is connected to a one-way valve (not shown), referred tocommonly in the art as an "Acme valve", or the pressure valve 100described hereinabove with reference to FIGS. 5 and 6. Once pressurizedfluid 60 stops flowing through aperture 62 into container 90, the fueldeliverer disconnects the fuel delivery equipment (not shown) fromcontainer 90, and the one-wave valve substantially prevents any leakageof fluid 60 to the environment. As long as there is a predeterminedamount of pressurized fluid 60 still present in tube 42 of valve 150,this amount of fluid is sufficient to overcome the force of spring 170and seat piston 48 against surface 58. As mentioned above, enlarged end50 of piston 48 preferably does not hermetically seal flow of fluid 60when in the position shown in FIG. 7B but rather a small amount of fluidis purposely allowed to leak into container 90, After this remainingfluid flows into container 90, and there is less than the predeterminedamount of pressurized fluid 60 present in tube 42, sprint, 170 thenurges piston 48 away from surface 58, and the container 90 is ready foruse by a consumer. As the consumer draws fluid from container 90, float154 gradually swings back to the position shown in FIG. 7A. Since spring170 has already urged piston 48 away from surface 58, float 154 hasvirtually no obstruction in its swinging travel.

Float 154 is preferably constructed of a sturdy and light material, suchas a very thin wall aluminum alloy. In order to prevent mechanicalrupture of the thin wall, a needle hole 174 is preferably formed in thewall of float 154, this hole being, sufficiently small such that onlyvapors and not liquid can enter float 154. The presence of hole 174causes equalization of vapor pressure within float 154 and outside float154 in container 90. Thus float 154 is still buoyed by fluid 60 insidecontainer 90 and hole 174 serves as a vent to prevent rupture of thefloat.

It will be appreciated by persons skilled in the art that the presentinvention is not limited by what has been particularly shown anddescribed hereinabove. Rather the scope of the present inventionincludes both combinations and subcombinations of the features describedhereinabove as well as modifications and variations thereof which wouldoccur to a person of skill in the art upon reading the foregoingdescription and which are not in the prior art.

What is claimed is:
 1. Pressurized fluid apparatus comprising:apressurized fluid container; a pipe arranged for flow therethrough of apressurized fluid into said container; a valve mechanism operativelyconnected to an end of said pipe disposed in said container; a branchinfluid communiation with said fluid container adapted for flowtherethrough of fluid from said fluid container for consumer use; andsaid mechanism having a float attached to a valve, wherein said float isbuoyed generally upwards by said pressurized fluid filling saidcontainer, such that when said float has been moved a predeterminedamount, said float closes said valve and substantially stops flow ofsaid pressurized fluid into said container, and wherein said valvemechanism, said branch and said pipe are insertable through an upperopening of said container as a single unit, and wherein said valvemechanism is rotatably attached to said pipe, said valve being closed byan angular upward movement of said float; characterized by said valvecomprising:a tube with a longitudinal bore having a longitudinal axisformed therein, and said valve including a piston slidingly disposed insaid tube, wherein only when said float is generally perpendicular tosaid longitudinal axis, said piston sealingly abuts an internal end faceof said tube, thereby closing said valve; said pressurized fluidapparatus further comprising:a bypass passageway extending along andaround at least a portion of said pipe in fluid communication with saidbranch for conducting therethrough fluid to said branch for consumeruse, even during filling of said container through said pipe. 2.Pressurized fluid apparatus according to claim 1 wherein said piston hasan enlarged end and said bore has an enlarged portion to accommodate andreceive therein said enlarged end, and wherein movement of said enlargedend along said longitudinal axis of said tube is constrained between ashoulder and an end surface of said enlarged portion of said bore. 3.Pressurized fluid apparatus according to claim 1 and wherein aninterface member extends from said piston and protrudes through anaperture formed in said tube, and said float is mounted on a float arm,and wherein an end of said float arm has a generally flat end portionwhich initially abuts against said interface member and a generallyarcuate portion which initially contacts a low-friction portion of saidinterface member, and wherein said piston sealingly abuts said internalend face of said tube only when said arcuate portion slides off saidlow-friction portion.
 4. Pressurized fluid apparatus according to claim1 and wherein an interface member extends from said piston and protrudesthrough an aperture formed in said tube, and said float is mounted on afloat arm, and wherein an end of said float arm has a generally flat endportion which initially abuts against said interface member and agenerally arcuate portion which initially contacts a low-frictionportion of said interface member, and wherein said piston sealinglyabuts said internal end face of said tube only when said flat endportion is rotated about 90° from said interface member.
 5. Pressurizedfluid apparatus according to claim 1 and wherein said piston is shapedto ensure laminar flow of a pressurized fluid therearound. 6.Pressurized fluid apparatus according to claim 1 and wherein said valvewhen closed is not hermetically closed.
 7. Pressurized fluid apparatusaccording to claim 1 and wherein a biasing device imparts a biasingforce on said piston, said biasing force being of a magnitude such thatif said tube contains a predetermined amount of said pressurized fluidthen predetermined amount is sufficient to overcome the biasing forceand seat said piston against said internal end face, and that if saidtube contains less than the predetermined amount, said biasing deviceurges said piston away from said internal end face of said tube. 8.Pressurized fluid apparatus according to claim 7 and wherein saidbiasing device is disposed in a bore formed in said piston. 9.Pressurized fluid apparatus according to claim 1 and wherein a needlehole is formed in a wall of said float, said hole being sufficientlysmall such that generally only vapors of said pressurized fluid and notliquid of said pressurized fluid can enter said float.